Neural probe with optical stimulation capability

ABSTRACT

A neural probe is disclosed for optically stimulating or silencing neurons and recording electrical responses to the stimulus. Using patterning techniques, an integral optical waveguide may be fabricated on the probe for transmitting neuron-affecting light from a light source to a probe tip. The probe tip may include one or more electrodes to receive electrical responses from stimulated neurons for recording or further processing. According to various embodiments, the disclosed neural probes may utilize multiple light sources simultaneously, switch between multiple light sources, or utilize a single light source to stimulate or silence multiple neuron locations simultaneously via multiple probe tips or via multiple light-emitting sites located along the length of the probe. Neural probes are thereby provided that have sufficient spatial resolution to accurately target, stimulate, and record the reaction of neurons, or as few as a single neuron, utilizing a slim, compact structure.

STATEMENT OF FEDERALLY-SPONSORED RESEARCH

This invention was made with government support under EEC9986866 awardedby the National Science Foundation. The government has certain rights inthe invention.

TECHNICAL FIELD

This invention relates generally to neural probes and, moreparticularly, to optical neural probes for accurately stimulating and/orrecording electrical responses of neurons.

BACKGROUND OF THE INVENTION

Massively-parallel access to the activity of large populations ofindividual neurons with high spatial and temporal resolution has been along-sought goal in neuroscience. With advances in MEMS andmicroelectronics, there has been significant progress toward this goalas planar fabrication processes have been applied to realize chronicextracellular microelectrode arrays. Many previously reported neuralprobes use electrical signals to stimulate neurons. However, suchelectrical stimulation can damage neurons. Additionally, because thenecessary electrical fields extend across large areas rather thanindividual neurons, such electrical stimulation can also suffer frompoor spatial resolution. To address these problems, an opticalstimulation method has been attempted with some success using an opticalfiber attached to a probe shank as the optical source (S. Royer et al.,“Recording and stimulation of single neurons in the hippocampus of thebehaving rat,” Society for Neuroscience Annual Meeting, 2008). However,this hybrid structure makes the probe bulky because the size of theoptical fiber is comparable to the size of the probe. Also, the hybridstructure is difficult to be accurately assembled and this structuremakes it difficult to control the target stimulation position.

SUMMARY OF THE INVENTION

According to one embodiment, there is provided a neural probe thatincludes a probe body, a shank extending from the probe body to a tip, alight-emitting diode (LED) light source attached to the tip forproviding neuron-affecting light at the tip, and one or more recordingelectrodes attached to the tip for receiving electrical responses to theneuron-affecting light.

According to another embodiment, there is provided a neural probe thatincludes a probe body, a shank extending from the probe body to a tip, alight-emitting diode (LED) light source patterned on the shank forproviding neuron-affecting light, and one or more recording electrodesattached to the tip for receiving electrical responses to theneuron-affecting light.

According to another embodiment, there is provided a neural probe thatincludes a probe body, a shank extending from the probe body to a tipand having an outer perimeter, a light-emitting diode (LED) light sourcepatterned at the tip for providing neuron-affecting light at the tip,and a plurality of recording electrodes for receiving electricalresponses to the neuron-affecting light, wherein the plurality ofrecording electrodes are attached to the tip such that they are closerto the outer perimeter of the shank than the LED light source.

BRIEF DESCRIPTION OF THE DRAWINGS

Preferred exemplary embodiments of the invention will hereinafter bedescribed in conjunction with the appended drawings, wherein likedesignations denote like elements, and wherein:

FIG. 1 is an exemplary neural probe including an optical waveguide and afiber optic light source;

FIG. 2 is a top view of a neural probe tip according to one embodiment;

FIG. 3 is a top view of a neural probe tip according to anotherembodiment;

FIG. 4 is a partial view of an exemplary neural probe including anedge-emitting LED light source;

FIG. 5 is a perspective view of a neural probe tip including LED lightsources mounted on the tip;

FIG. 6 is a cross-sectional view through the probe body and fiber opticof the exemplary neural probe of FIG. 1;

FIG. 7 is a cross-sectional view through the tip of the exemplary neuralprobe of FIG. 1;

FIG. 8 is a partial view of FIG. 7 showing an alternative embodiment ofa waveguide cladding layer;

FIG. 9 is an exemplary neural probe including an optical mixer andmultiple light sources;

FIG. 10 is an exemplary neural probe including an optical splitter andmultiple probe tips;

FIG. 11 is a top view of a neural probe shank including multipleelectrode array regions;

FIG. 12 is an enlarged view of a portion of FIG. 11, showing a lightemitting junction;

FIG. 13 shows an exemplary method of fabricating a neural probeaccording to one embodiment;

FIG. 14 is a plot of optical signal loss per waveguide unit length foran exemplary neural probe; and

FIG. 15 shows an exemplary method of fabricating a neural probeaccording to another embodiment.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Described below are exemplary embodiments of an optical neural probethat may have sufficient spatial resolution to accurately target,stimulate, and record the reaction of neurons, or as few as a singleneuron, utilizing a slim, compact structure. In general, the disclosedembodiments of the optical neural probe utilize structures that emitneuron-affecting light to selectively target neurons and that includerecording electrodes near the region of light emission to receive anyelectrical responses from the targeted neuron or neurons and transmitthe responses to a location to be recorded or processed. Theneuron-affecting light can be used to stimulate or silence individual orgroups of neurons. Such light can include visible and/or non-visiblelight. Stimulation or silencing of multiple sites is made possible bycertain variations of the disclosed probe, as well as stimulation orsilencing by more than one wavelength of light either simultaneously orsequentially. Although the following description at times refers tolight stimulation of neurons and sites, without specifically mentioningthe use of light to silence neurons, it will be appreciated by thoseskilled in the art that the light can be used for either or bothpurposes, depending on such things as the wavelength and intensity ofthe emitted light.

Referring to FIG. 1, a neural probe 10 is shown, according to oneembodiment. The exemplary neural probe includes a probe body 12, a shank14 extending from the probe body 12 to a tip 16, one or more recordingelectrodes 18, electrode leads 20, and a light source 22 for emittingneuron-affecting light at the tip 16. As shown in FIG. 1, probe 10 maybe attached to and/or supported by a printed circuit board (PCB) 24.Probe body 12 generally serves as the portion of the probe from whichshank 14 extends and where various probe electrical connections arelocated. It may be constructed from a heavily boron doped single crystalsilicon. In this embodiment, probe body 12 and shank 14 areintegral—i.e., formed together as one piece. Probe body 12 includeselectrical connections 26, which may be gold pads or anotherelectrically conductive material, for electrical communication with PCB24 and/or some other component. Probe body 12 may also include a groove28 for supporting and positioning light source 22, as will be discussedin more detail below.

Shank 14 has an outer perimeter 15 and extends from the probe body 12 tothe tip 16 and supports electrodes 18 and electrode leads 20. It shouldbe noted that FIG. 1 is not necessarily to scale. For example, shank 14may appear needle-like in shape when viewed actual size, with tip 16 atthe point of the needle-like shape. In one embodiment, the shank 14 canextend from about 1-7 mm, preferably about 5 mm, in length from theprobe body. The shank has a width transverse to the length ranging from50-150 μm, and a thickness from about 10-20 μm. Of course, these areonly exemplary ranges, and several factors may be considered whenselecting the dimensions of the shank 14, such as strength, desireddepth of probing, and the number of electrodes 18 desired, to name afew. In this embodiment, shank 14 also supports a portion of an opticalwaveguide 30, as will be discussed below.

Tip 16 is at the end of shank 14 furthest from the probe body 12 and ispointed in this embodiment. Recording electrodes 18 are located andattached to tip 16 and may be arranged in an array generally positionedabout the perimeter or edge of the tip 16. The electrodes 18 can receiveelectrical responses from neurons when stimulated by the emitted light.In some embodiments, electrodes 18 may be located elsewhere, along theshank 14, for example, where neuron-affecting light may be emitted. Theelectrodes 18 may be iridium electrodes, or they can be constructed fromother suitable materials with low impedance, such as iridium oxide,other metals, or carbon nanotubes, for example.

Electrode leads 20 extend along shank 14 to electrically connect eachelectrode to the probe body 12. Though not explicitly shown in FIG. 1,each lead 20 may be electrically connected to one of the connections 26at the probe body for communication with PCB 24, where provided, orother components or devices. Leads 20 may be about 0.5 μm thick (raisedfrom the surface of the shank) and range from about 2-5 μm wide.Electrode leads 20 transmit electrical responses received by electrodes18 from stimulated neurons to the probe body 12. The electricalresponses can be sent through electrical connections 26 to PCB 24, whereprovided, for processing there or at another location external to thePCB. For example, as shown in FIG. 1, conductive bonding wires 32 canprovide electrical connections between the probe 10 and the PCB. The PCB24 can communicate through a cable 34, as shown, or through other means,with a computer, controller, data-logger, or other equipment.Alternatively, or in addition to connection to an external controller, acontroller or control circuit may be integrated with the probe 10 bymounting the controller directly on the probe body 12 for massivelyparallel access.

Light source 22 provides neuron-affecting light for emission nearrecording electrodes 18, in this case at tip 16. In this embodiment,light source 22 is a fiber optic light source. Fiber optic light source22 works together with optical waveguide 30 to emit light near recordingelectrodes 18. The embodiment shown in FIG. 1 includes an integratedoptical waveguide 30 extending along the length of the shank 14 from theprobe body 12 to the tip 16. The optical waveguide 30 is supported byand attached to the shank 14. The waveguide 30 abuts the fiber opticlight source 22 at a source end 36 and extends to the tip 16 at anemitting end 38. The fiber optic may be coupled to an external lightsource (not shown) to deliver light to the optical waveguide and mayalso include one or more cladding layers 40. In the embodiment shown inFIG. 1, the emitting end 38 of waveguide 30 lies near the end of tip 16to provide light at the end of the tip. However, end 38 mayalternatively lie within an electrode array region 25, or the waveguide30 may extend along shank 14 from the probe body 12 such that it doesnot extend into the electrode array region, so long as the lightintensity is sufficient to stimulate neurons near the electrodes 18 fromemitting end 38.

For example, FIGS. 2 and 3 show embodiments in which waveguide 30 doesnot extend to the end of tip 16, yet is constructed and oriented on theshank 14 to provide neuron-affecting light at its tip 16. FIG. 2illustrates an exemplary tip 16′ where emitting end 38 of opticalwaveguide 30 lies within the electrode array region 25′ so that some ofthe electrodes 18 are nearer the probe body than emitting end 38, andother electrodes 18 are further from the probe body than is emitting end38. FIG. 3 illustrates an exemplary tip 16″ where end 38 of opticalwaveguide 30 lies outside of the electrode array region 25″ so that allof the electrodes 18 are further from the probe body than is emittingend 38. The arrangement of FIG. 3 may be useful with shanks or tipshaving relatively small widths so that the electrode leads 20 can berouted around the end 38 of the waveguide 30, as shown, for access toelectrodes 18 at the end of tip 16.

As indicated, the cross-sectional area of the optical waveguide 30 maybe only a small fraction of the cross-sectional area of the fiber opticlight source 22. For example, a typical fiber optic for use in anoptical neural probe may have a clad diameter of about 125 μm, or across-sectional area of about 0.012 mm². Optical waveguide 30 may have aclad width of about 20-30 μm and a clad thickness of about 15-25 μm sothat the cross-sectional area may range from about 300-750 μm². Even atthe top end of the range, optical waveguide 30 has a cross-sectionalarea that is more than an order of magnitude less than thecross-sectional area of the abutting optical fiber, allowing light to betransmitted to the tip of the probe without the bulk of the opticalfiber itself extending the length of the probe. As used herein, the term“clad” when placed before a dimensional description such as “cladthickness” or “clad diameter” is meant to describe an overall dimensionof the waveguide or fiber optic, including any cladding layerssurrounding the optical core.

Light sources other than fiber optic light sources may be coupled tosource end 36 of waveguide 30. In one embodiment, illustrated in FIG. 4,the light source 22′ is an edge-emitting LED. Neuron-affecting light isemitted from the side of the LED structure, and the emitting region ofthe LED is comparable in size to the cross-section of the waveguide 30.Various combinations and variations of light sources and fiber opticsmay also be used to deliver light to the waveguide 30. For example, aprobe body-mounted LED may be combined with an optical fiber to deliverlight to the waveguide 30.

FIG. 5 illustrates another embodiment where the light source 22″includes one or more LEDs located and mounted directly on the tip 16 ofthe probe, or otherwise near the recording electrodes 18. The LEDs22″can be organic LEDs (OLEDs), according to one embodiment. OLEDmaterial can be patterned directly at or near the probe tip 16 withtransparent electrodes. Separate electrical connections 42 are providedto control the LEDs. It is possible to use several different lightsources on a single probe by patterning different OLED materials. Forexample, LEDs that emit different wavelengths of light (e.g., blue,yellow, and/or non-visible wavelengths) may be used in combination withone another to simultaneously or sequentially provide light at tip 16that stimulates or silences individual neurons. This arrangement caneliminate the need for a waveguide, optical fibers, and external lightsources. Alternatively, patterned OLEDs such as those in FIG. 5 can beused in combination with one or more waveguides and additional lightsources for further control over the neuron stimulation and responserecording process.

Referring to FIG. 6, a cross-section through the probe body 12 of FIG. 1is shown. A groove 28 may be included in the probe body 12 to aid inalignment of the fiber optic light source 22 with the waveguide. In thisexample, a V-shaped groove is illustrated, but the groove 28 may takeother forms such as a U-shaped groove or other shape suitable to supportand align the core 44 of the optical fiber with the waveguide. In thisembodiment, surface 46 represents a <111> plane. Similar types ofgrooves may be used to align other types of light sources, such as LEDs,with the waveguide. The groove 28 can be made by anisotropic etching ofsilicon in KOH or by other methods suitable to accurately control thedepth and shape of the groove.

Turning now to FIG. 7 for further description of exemplary waveguide 30,a cross-section is shown of the tip 16 of the probe of FIG. 1, again notnecessarily to scale. In this embodiment, waveguide 30 includes a core50, a bottom cladding layer 52, and a top cladding layer 54, where thebottom and top cladding layers 52, 54 are separate from each other. Thebottom cladding layer 52 may be an oxide, for example, and the topcladding layer 54 covering the top and sides of the waveguide core 50may be a polymer layer and/or a dielectric layer. In this particularstructure, cladding layer thickness may be limited to approximately 3μmdue to the limitations of conventional fabrication techniques.Additionally, when patterning thicker layers, the resulting surfacemorphology can limit additional processing on top of the thicker layers.Further, the stress of a thick film is difficult to release in thestructure.

FIG. 8 shows another embodiment in which bottom cladding layer 52′ isincreased in thickness to about 10 μm or more. In order to produce abottom cladding layer 52′ having a thickness above 3 μm, the structurecan be modified as shown using special fabrication techniques such assilicon oxide-glass hybrid structure using a glass-melting process. Inthis structure, in addition to the thickness of bottom cladding layer52′ being 10μm or more, a stress-free structure can be obtained. Inanother embodiment, the top cladding material shown in FIGS. 7 and 8 cancontinue around the bottom of the waveguide core 50 to completelyencapsulate the core.

Optical waveguide 30 may include a core 50, as shown in FIGS. 7 and 8,and at least one cladding, whether continuous or including bottom andtop layers. Generally, it is preferred that the refractive index of thecore material be higher than that of the cladding material or materialsto effectively guide light through waveguide 30. The core 50 can beconstructed from a polymeric material such as SU-8, or other polymer, orfrom dielectric materials having a suitable refractive index. One ormore additional cladding layers can be included with the waveguide 30 tominimize optical losses. Various materials such as oxides or polymersthat have lower refractive indices than that of the core material can beused as the cladding layer or layers, and overall cladding thickness maybe increased to a level suitable to minimize optical losses. The opticalwaveguide 30 may also include one or more optical branches along itslength in applications in which it is desirable to stimulate multiplesites simultaneously, or in applications where it is desired to transmitmore than one different light source to the tip of the probe.

For example, FIG. 9 illustrates exemplary neural probe 110, includingall of the same types of elements as exemplary probe 10 of FIG. 1.However, in this embodiment the optical waveguide 130 includes twobranches 160, 160′, an optical mixer 162, and a shank portion 164. Eachof the branches 160, 160′ extends from its respective source end 136,136′ and along probe body 112, merging at the optical mixer 162. Theshank portion 164 extends from the optical mixer 162 toward the tip 116of the probe to emitting end 138, as with other waveguides previouslypresented herein. Waveguide 130 may thus be coupled with two differentlight sources 122, 122′ at source ends 136, 136′. In the embodimentshown, light sources 122, 122′ include fiber optics, but otherpreviously described light sources may be used as well, and each may bea different type of light source in some instances. With thisconstruction, neural probe 110 can stimulate or silence neurons at adesired location by emitting light having variable characteristics fromthe emitting end 138 of the waveguide 130. For example, two differentwavelengths of light may be emitted from end 138. This can beaccomplished by switching from one light source 122 to the other source122′ and vice versa. If both light sources 122, 122′ providing differentwavelengths of light are simultaneously illuminated with different pulsemodulations when targeting a neuron or neurons, various opticalperturbation patterns of the targeted neurons can be expected. Theintensity or power of the light may vary by source as well. Withmultiple light sources, the size of the probe body 112 may increasecompared to probes having a single light source such as probe 10 ofFIG. 1. This is due to the extra length of waveguide material necessaryto gradually merge the two branches 160, 160′ at optical mixer 162.While the embodiment shown in FIG. 9 includes two light sources, thenumber of light sources can be increased to three or more withadditional optical mixers used to merge three or more branches into onefor extension toward the probe tip. In such embodiments the number ofoptical mixers can vary as well. A single optical mixer may be capableof merging three or more branches, or multiple mixers may be used tomerge individual branches before additionally merging the mergedbranches.

FIG. 10 illustrates another exemplary neural probe 210, including all ofthe same types of elements as exemplary probe 10 of FIG. 1. However, inthis embodiment the optical waveguide 230 includes two branches 260,260′, an optical splitter 262, and a body portion 264. Body portion 264extends from source end 236 and along probe body 212 to the opticalsplitter 262. Each of branches 260, 260′ extends away from the opticalsplitter 262 and gradually away from each other along probe body 212 andtoward the two shanks 214, 214′. Each branch further extends along itsrespective shank 214, 214′ toward the two tips 216, 216′ of the probe toemitting ends 238, 238′. Waveguide 230 may thus split a single lightsource 222 and direct the light to more than one emitting end lyingalong more than one shank or probe tip. In the embodiment shown, lightsource 222 includes a fiber optic, but other previously described lightsources may be used as well. With this construction, neural probe 210can stimulate or silence neurons at multiple locations simultaneouslyfrom a single light source. This can significantly reduce the efforts inpackaging. As with the embodiment of FIG. 9, the length of the probebody 212 may increase compared to probes having a single shank such asprobe 10 of FIG. 1. This is due to the extra length of waveguidematerial necessary to gradually separate the two branches 260, 260′ asthey extend away from optical splitter 262. While the embodiment shownin FIG. 10 includes two branches, the number of branches can beincreased to three or more with additional optical splitters, so long aseach branch can emit sufficient light at its emitting end to stimulateneurons. Of course, an optical splitter is not necessary to provideneural stimulation to more than one location simultaneously. A neuralprobe may be constructed that includes more than one shank extendingfrom the probe body. Each shank can support separate waveguides, eachhaving independent light sources, and some shanks may not include awaveguide, but may include other light sources to provide light at theirrespective tips. In other embodiments, both an optical splitter and anoptical mixer can be used to permit use of multiple light sources and topermit stimulation or silencing of neurons from multiple light-emittingsites.

The optical probes disclosed herein are not limited to neuron-affectinglight emission only at the tip of the probe. For example, FIG. 11illustrates a portion of one example of a neural probe 310 includingshank 314 that includes more than one electrode array region 325 and325′. Shank 314 can be used with any of the other various probe bodies,light sources, optical splitters or mixers, etc. disclosed herein.Electrode array region 325 is similar to some previously describedelectrode arrangements—i.e., it is located at the probe tip 316 with anarray of electrodes 318 arranged about the edge or perimeter of the tip316. Waveguide 330 extends from a source end (not shown) located at theprobe body, along shank 314 and toward tip 316, to an emitting end 338.Waveguide 330 in this example does not extend all the way to the end oftip 316. Emitting end 338 lies at or near array region 325 at the endthat is nearest the probe body (not shown).

Exemplary shank 314 further includes a second electrode array region325′ located along the shank between the probe body and the probe tip316. As with other electrode arrays, the array of region 325′ includeselectrodes 318 disposed near the perimeter or edge of the shank 314, butin this case not at the probe tip 316. In this case, electrodes 318 arelocated approximately mid-way between the probe body and the probe tip.Of course, in order for the electrodes 318 to receive electricalresponses from neurons in their proximity, the neurons must bestimulated, preferably with light energy. To facilitate this, waveguide330 includes light emitting junction 370.

Referring to FIG. 12, junction 370 is formed where two portions ofwaveguide 330 meet, the two portions having different cross-sectionalareas in this embodiment. More particularly, the larger cross-sectionportion of waveguide 330 extends from the source end of the waveguide(right side of Figure) and the smaller cross-section portion extendsfrom the emitting (left side of Figure). The different-sizedcross-sections form a step or transition at the junction 370. Thejunction 370 may be located near array region 325′, preferably at theend of the array region nearest the probe body and light source asshown. The foregoing description is not to say that the source end andthe emitting end of the waveguide are separate pieces that are placedtogether to form a “junction” in the waveguide; e.g., it may bepreferable to pattern the waveguide directly into such a shape having across-section that changes along its length. Apart from a step ortransition in the width or other cross-sectional shape of the waveguide330, notches, surface roughening, or other optical features can beprovided on the waveguide to effect light emission at differentlocations along the shank.

As previously described, waveguide 330 typically includes one or morecladding layers to help contain the light travelling through its core.In order to allow junction 370 to emit light, the cladding material ormaterials are selectively omitted or removed from the junction. Inparticular, cladding material is selectively omitted or removed,exposing waveguide core material, on portions of the junction facing thearray region 325′ and its electrodes 318. Cladding material is thereforeomitted at transition regions 372 and 374 as indicated. The transitionregions may be specifically designed and patterned to emit light in thedesired direction, based on the location of the electrodes 318 in arrayregion 325′. In this manner, light from the probe light source istransmitted from the source end and through the larger cross-sectionportion of waveguide 330 to light emitting junction 370. Becausecladding material is not present at or near the transition regions 372or 374, some of the light is emitted through the transition regionsurfaces, while the remainder of the light is transmitted through thesmaller cross-section portion of the waveguide 330 to the emitting end.

Thus, exemplary probe 310 may be considered to include threelight-emitting sites—i.e., one at the probe tip, and two near electrodearray region 325′ on opposite sides of the waveguide 330—therebyallowing simultaneous neuron stimulation at multiple stimulation zones375 from a single waveguide along with the collection of electricalresponses at corresponding multiple positions along shank 314. Eachstimulation zone extends from a light-emitting site, such as emittingend 338 or transition regions 372, 374, located on the shank to variouspoints beyond the outer perimeter 315 of the shank, as shown. Eachstimulation zone 375 represents a region from which neural electricalresponses to stimulation or silencing are desired to be recorded and/ora region that receives sufficient neuron-affecting light to stimulate orsilence neurons. In this embodiment, each stimulation zone 375 partiallyoverlaps one of the array regions 325 or 325′, by virtue of the positionof each light-emitting site in relation to each stimulation zone.

In this exemplary configuration, and as best shown in FIG. 11, theportion of shank 314 nearest the probe body is wider than the portion ofshank 314 nearest the probe tip 316, with the width transition generallycorresponding to junction 370 in overall lengthwise position along theshank. The larger width of the shank on the probe body side of thejunction may be necessary to accommodate the electrode leads 320 for theelectrodes 318 lying in array region 325′.

Exemplary neural probes can be constructed using a variety oftechniques. A method according to one embodiment is illustrated incross-section in FIG. 13, where layer thicknesses are not to scale andare enlarged for clarity. In this method, boron 82 is first diffusedinto the silicon substrate 80 to form a layer for the probe structure.Then, an oxide/nitride/oxide layer 84 is deposited as a dielectric forstress compensation, and poly-silicon 86 is deposited forinterconnections. Next, another dielectric layer 88 is deposited andpatterned as a bottom cladding layer for the waveguide. Iridiumrecording electrodes 90 are deposited and patterned at the desiredelectrical recording sites, and gold pads 92 are deposited and patternedfor electrical connections. Next, an SU-8 optical core 94 is patternedon the cladding oxide layer to produce the optical waveguide core 94. AU-shaped groove 96 is patterned using deep reactive-ion etching (DRIE)for eventually supporting a fiber optic light source at one end of thewaveguide (groove 98 is shown in cross-section through the longitudinalcenter of the U-shape). Finally, the probe 100 is released by wetetching in EDP by using a boron layer as an etch stop layer, as shown inthe bottom image of FIG. 13. This method may of course include one ormore additional steps, and some steps may be omitted from the process asnecessary.

For experimental purposes, an exemplary neural probe was constructedsimilar to that illustrated in FIG. 1 using the above method. Blue light(475 nm) was used for experimental measurements. The light wastransmitted from an external light source to the probe tip through afiber optic and an optical waveguide. The tip of the experimental probe,more particularly the emitting end of the waveguide, was successfullyilluminated. Optical characteristics of the fabricated probe weremeasured and are shown in FIG. 14. An optical power meter was used todetermine coupling losses and waveguide losses using optical waveguidesof various lengths. The coupling loss at the interface of the fiberoptic and the waveguide was determined to be about −3.7 dB (57%), andthe waveguide loss was determined to be about −0.22 dB(4.9%)/mm. Aninput power of 2.5 mW was used in the experiments. The output power atthe tip was measured to be 0.31 mW, which is sufficient for stimulatingneurons (E. Boyden et al, “Millisecond-timescale, genetically targetedoptical control of neural activity,” Nature Neuroscience, vol. 8, pp.1263-1268, 2005).

A method for constructing an exemplary neural probe according to anotherembodiment is illustrated in cross-section in FIG. 15, where layerthicknesses are not to scale and are enlarged for clarity. Although someelement numbers in FIG. 15 correspond with similar elements of FIG. 13,not all numbers necessarily correspond with similar elements betweenfigures. In this method, instead of using a bulk wafer, asilicon-on-insulator (SOI) wafer 80′ is used for accurate control of thethickness of the probe shank. SOI wafer 80′ includes a buried oxidelayer 82′. The thickness of the buried oxide layer is about 2 μm and thethickness of the top Si layer is about 15 μm. The wafer 80′ is thenthermally oxidized to form an oxide layer 84′. A poly-silicon layer 86′is then deposited and doped with boron for interconnections and may havea thickness of about 500 nm. After patterning the poly-silicon andgrowing an additional oxide layer 88′, iridium and gold are patternedfor recording electrodes 90′ and bonding pads 92′, respectively. AfterPECVD oxide cladding layer 93′ for the bottom of the waveguide ispatterned, a layer of SU-8 94′ may be patterned for the waveguide. ThePECVD oxide layer 93′ may be about 3 μm thick, and the SU-8 layer 94′may be about 15 μm thick. One or more grooves 96′ to accommodate opticalfibers may be etched using DRIE. Finally, the probes may be released bysilicon etching from the top and the bottom.

Among the other features of the types of probe fabrication describedherein is the ability to form low-profile, integral waveguides. Awaveguide formed in this manner may be attached to other underlyingprobe components continuously along its entire length, can be formed inplace in a nearly limitless number of various fixed shapes, and can beformed having cross-sectional dimensions much smaller than a typicaloptical fiber. For example, as noted, the waveguide core in this exampleincludes SU-8 that may be about 15 μm thick, or about 20-25 μm with topand bottom cladding, while a typical optical fiber may be about 125 μmin diameter with cladding.

For experimental purposes, exemplary neural probes were fabricatedsimilar to those illustrated in FIGS. 9 and 10 using the above method.Each probe that was fabricated included a branched waveguide: one withan optical mixer for use with multiple different light sources, and onewith an optical splitter and multiple shanks for use with a single lightsource and multiple light-emitting tips. The probe with the opticalmixer also included a shank and waveguide similar to that shown in FIGS.11-12, where the probe included more than one electrode array region andthe waveguide included a light-emitting junction.

Each of the fabricated probes were fitted with single-mode opticalfibers (D=125 μm, Thorlabs, 460HP) as the light source or sources forthe respective waveguides. Blue light (473 nm) was used for experimentalmeasurements. Both the probe including the optical mixer and the probeincluding the optical splitter visually demonstrated successfultransmission of the light along the curved waveguides to the end of the5 mm shanks. In addition, the two additional light-emitting sites at theexperimental waveguide light-emitting junction also successfullydemonstrated light-emission.

An input power of 6.5 mW was applied from the single-mode optical fiberto the waveguide that included the optical mixer. Output power at allthree light-emitting sites was measured. Power at the light-emitting endof the waveguide near the tip of the probe was measured and determinedto be 35 μW. Power at each side of the shank at the light-emittingjunction was measured and determined to be 15 μW at each side of theshank. With the same power applied to the source end of the waveguidehaving the optical splitter and two shanks, the power at each of thelight-emitting ends after the splitter was measured and determined to be50 μW. All of these output power levels are sufficient to stimulateneurons.

In addition to demonstrating successful transmission of light throughthe patterned waveguides, electrical performance of the recordingelectrodes was also verified by placing each probe tip, non-illuminated,in an electrolyte solution with a reference electrode immersed in thesolution. A 1.75 kHz sinusoidal wave was applied to the immersedreference electrode, and electrical signals output from each probe wererecorded with a neural data acquisition system (Plexon, Inc.). Theoutput signal from each probe included a corresponding sinusoidal waveof the same frequency.

It is to be understood that the foregoing description is of one or morepreferred exemplary embodiments of the invention. The invention is notlimited to the particular embodiment(s) disclosed herein, but rather isdefined solely by the claims below. Furthermore, the statementscontained in the foregoing description relate to particular embodimentsand are not to be construed as limitations on the scope of the inventionor on the definition of terms used in the claims, except where a term orphrase is expressly defined above. Various other embodiments and variouschanges and modifications to the disclosed embodiment(s) will becomeapparent to those skilled in the art. All such other embodiments,changes, and modifications are intended to come within the scope of theappended claims.

As used in this specification and claims, the terms “for example,” “forinstance,” and “such as,” and the verbs “comprising,” “having,”“including,” and their other verb forms, when used in conjunction with alisting of one or more components or other items, are each to beconstrued as open-ended, meaning that the listing is not to beconsidered as excluding other, additional components or items. Otherterms are to be construed using their broadest reasonable meaning unlessthey are used in a context that requires a different interpretation.

1. A neural probe, comprising: a probe body; a shank extending from theprobe body to a tip; a light-emitting diode (LED) light source attachedto the tip for providing neuron-affecting light at said tip; and one ormore recording electrodes attached to said tip for receiving electricalresponses to the neuron-affecting light.
 2. A neural probe as defined inclaim 1, wherein the LED light source is located near the one or morerecording electrodes.
 3. A neural probe as defined in claim 2, whereinthe one or more recording electrodes comprise a plurality of recordingelectrodes, and wherein the LED light source is located between at leastsome of the plurality of recording electrodes.
 4. A neural probe asdefined in claim 1, comprising a plurality of the LED light sourcesattached to the tip.
 5. A neural probe as defined in claim 4, wherein atleast two of the plurality of LED light sources are in a staggeredconfiguration.
 6. A neural probe as defined in claim 4, wherein one ofthe LED light sources is located closer to the tip than at least oneother of the LED light sources.
 7. A neural probe as defined in claim 4,wherein the plurality of LED light sources simultaneously orsequentially provide neuron-affecting light at said tip.
 8. A neuralprobe as defined in claim 4, wherein at least two of the plurality ofLED light sources each emit a different wavelength of light than theother.
 9. A neural probe as defined in claim 8, wherein one wavelengthof light stimulates a neuron and another wavelength of light silences aneuron.
 10. A neural probe as defined in claim 4, wherein the pluralityof LED light sources have separate electrical connections to control theplurality of LED light sources.
 11. A neural probe as defined in claim10, comprising a plurality of recording electrodes having separateelectrical connections, and the electrical connections for the pluralityof recording electrodes are located on either side of the electricalconnections for the LED light sources.
 12. A neural probe as defined inclaim 1, wherein the LED light source is an edge-emitting LED forproviding neuron-affecting light from a side of the LED light source.13. A neural probe as defined in claim 1, further comprising an opticalwaveguide extending from a source end at the probe body to an emittingend near said tip, wherein a second light source is in communicationwith the source end and the neuron-affecting light is provided at thetip by emitting end and the LED light source.
 14. A neural probe asdefined in claim 13, wherein the second light source comprises a fiberoptic having a first end in communication with an external light sourceand a second end abutting the source end of the optical waveguide.
 15. Aneural probe as defined in claim 13, wherein the second light sourcecomprises an LED light source mounted adjacent the source end of theoptical waveguide.
 16. A neural probe as defined in claim 1, wherein theLED light source is an organic light-emitting diode (OLED) light source.17. A neural probe as defined in claim 1, further comprising a secondshank extending from the probe body to a second tip and a secondlight-emitting diode (LED) light source attached to the second tip forproviding neuron-affecting light at said second tip.
 18. A neural probe,comprising: a probe body; a shank extending from the probe body to atip; a light-emitting diode (LED) light source patterned on the shankfor providing neuron-affecting light; and one or more recordingelectrodes attached to said tip for receiving electrical responses tothe neuron-affecting light.
 19. The neural probe of claim 18, whereinthe patterned LED light source includes a transparent electrode.
 20. Theneural probe of claim 18, further comprising at least one other LEDlight source patterned on the shank, and wherein the LED light sourcesare organic light-emitting diode (OLED) light sources patterned fromdifferent OLED materials.
 21. The neural probe of claim 18, wherein theone or more recording electrodes have an electrical connection and theLED light source, the recording electrodes, and the electricalconnections for the one or more recording electrodes are patterned on anouter surface of the shank.
 22. A neural probe, comprising: a probebody; a shank extending from the probe body to a tip and having an outerperimeter; a light-emitting diode (LED) light source patterned at thetip for providing neuron-affecting light at said tip; and a plurality ofrecording electrodes for receiving electrical responses to theneuron-affecting light, wherein the plurality of recording electrodesare attached to said tip such that they are closer to the outerperimeter of the shank than the LED light source.